WO2014200303A1

WO2014200303A1 - Apparatuses and methods for encoding and decoding of parity check codes

Info

Publication number: WO2014200303A1
Application number: PCT/KR2014/005203
Authority: WO
Inventors: Se-Ho Myung; Hong-Sil Jeong; Kyung-Joong Kim
Original assignee: Samsung Electronics Co., Ltd.
Priority date: 2013-06-14
Filing date: 2014-06-13
Publication date: 2014-12-18
Also published as: US9362952B2; US20140372826A1

Abstract

An encoding apparatus is provided. The encoding apparatus includes: a low density parity check (LDPC) encoder configured to generate an LDPC codeword formed of 16200 bits by performing LDPC encoding based on a parity check matrix, wherein the parity check matrix includes an information word sub-matrix and a parity sub-matrix, the information word sub-matrix being formed of a plurality of column groups each including 360 columns and being defined as a table indicating a position of one (1) present in each 360-th column.

Description

[DESCRIPTION] [Invention Title]

APPARATUSES AND METHODS FOR ENCODING AND DECODING OF PARITY CHECK CODES

[Technical Field]

Apparatuses and methods consistent with exemplary embodiments relate to encoding and decoding of parity check codes, and more particularly, to encoding and decoding of parity check codes capable of performing low density parity check (LDPC) encoding and decoding based on a parity check matrix.

[Background Art]

In a communication/broadcasting system, link performance may be significantly deteriorated due to several types of noise in a channel, a fading phenomenon, and inter-symbol interference (ISI). Therefore, in order to implement high speed digital communication/broadcasting systems requiring a high data throughput and reliability, such as the next generation mobile communication, digital broadcasting and portable Internet, it has been required to develop a technology to address problems occurring from the noise, fading, ISI, etc. Studies on an error correcting code has been recently conducted actively as a method for increasing reliability of communication by efficiently reconstructing distorted information.

In the 1960s, an LDPC code initially introduced by Gallager has been forgotten for a long time due to technological complexity of the LDPC code that could not be implemented by a technology level in those days. However, as a turbo code suggested by Berrou, Glavieux, and Thitimajshima in 1993 shows performance approaching a channel capacity of Shannon, many analyses for performance and features of the turbo code have been conducted. Therefore, many studies on channel encoding based on a graph and iterative decoding have been conducted. As a result, the LDPC code was again studied in the latter half of the 1990s, such that is has been revealed that the performance approaches the channel capacity of the Shannon when decoding is performed by applying iterative decoding based on a sum-product algorithm on a Tanner graph corresponding to the LDPC code. The LDPC code is generally defined as a parity check matrix and may be represented by. a bipartite graph commonly called a Tanner graph.

Hereinafter, a systematic LDPC codeword will be described with reference to FIG. 1. The LDPC codes are LDPC encoded by receiving an information word 102 formed of Κ_Μρς bits or symbols to generate a codeword 100 formed of N_ldpc bits or symbols. Hereinafter, for convenience of explanation, it is assumed that the codeword 100 formed of Ni_dpc bits is generated by receiving the information word 102 including Ki_dpc bits. That is, when the information word *** 102 which is formed of K,_dpc input bits is LDPC c⁼[^c0»^c l>^c2»^C3»^, " »^C _Uki-l ]

encoded, the codeword 100 is generated. That is, the codeword is a bit string formed of a plurality of bits and the bits of the codeword represent each bit forming the codeword. Further, the information word is a bit string formed of a plurality of bits and the bits of the information word represent each bit forming the information word. In this case, in the case of a systematic code, the codeword is formed of

Here,

^J is a parity 104 and the number N_parity of parity bits is as follows. N_parity = id_pc - Kidp_C.

The LDPC codes are a kind of linear block codes and include a process of determining a codeword satisfying conditions of following mathematical expression 1.

w ere

In mathematical expression 1 above, H represents the parity-check matrix, C represents the codeword, q represents an i-th bit of the codeword, and N_ldpc represents a codeword length. Here, h; represents an i-th column of the parity-check matrix H. The parity-check matrix H is formed of the same N|_dpc columns as the number of bits of the LDPC codeword. The mathematical expression 1 represents that since a sum of a product of the i-th column h; of the parity-check matrix and the i-th bit C; of the codeword becomes "0", the i-th column h; has a relationship with the i-th bit c; of the codeword.

Meanwhile, the performance of the LDPC codes may be determined according to the parity-check matrix. Therefore, there is a need to design the parity-check matrix for the LDPC codes having improved performance.

[Disclosure] [Technical Problem]

One or more exemplary embodiments of the inventive concept may overcome the above disadvantages and other disadvantages not described above. However, these embodiments are not required to overcome the disadvantages and any of the problems described above.

One or more exemplary embodiments provide apparatuses and methods for encoding and decoding of parity check codes capable of improving LDPC encoding and decoding performance.

[Technical Solution]

According to an aspect of an exemplary embodiment, there is provided an encoding apparatus for performing low density parity check (LDPC) encoding which may include: an LDPC encoder configured to generate an LDPC codeword formed of 16200 bits by performing LDPC encoding based on a parity check matrix, wherein the parity check matrix includes an information word sub-matrix and a parity sub-matrix, the information word sub-matrix being formed of a plurality of column groups each including 360 columns and being defined as a table indicating a position of one (1) present in each 360-th column.

The LDPC encoder may perform the LDPC encoding using a parity check matrix defined as a table such as Table 6 when a code rate of an LDPC code is 7/15.

The LDPC encoder may perform the LDPC encoding using a parity check matrix defined as a table such as Table 10 when the code rate is 5/15. The LDPC encoder may perform the LDPC encoding using a parity check matrix defined as a table such as Table 11 when the code rate is 9/15.

The LDPC encoder may perform the LDPC encoding using a parity check matrix defined as a table such as Table 13 when the code rate is 11/15.

The LDPC encoder may perform the LDPC encoding using a parity check matrix defined as a table such as Table 14 when the code rate is 13/15.

According to an aspect of another exemplary embodiment, there is provided an encoding method for performing LDPC encoding which may include: generating an LDPC codeword formed of 16200 bits by performing the LDPC encoding on input bits based on a parity check matrix, wherein the parity check matrix includes an information word sub-matrix and a parity sub-matrix, and the information word sub-matrix has a plurality of column groups each including 360 columns and being defined as a table indicating positions of one (1) present in each 360-th column.

In the generating the LDPC codeword, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 6 when the code rate is 7/15.

In the generating the LDPC codeword, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 10 when the code rate is 5/15.

In the generating the LDPC codeword, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 11 when the code rate is 9/15.

In the generating the LDPC codeword, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 13 when the code rate is 11/15.

In the generating the LDPC codeword, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 14 when the code rate is 13/15.

According to an aspect of still another exemplary embodiment, there is provided a decoding apparatus for performing LDPC decoding which may include: an LDPC decoder configured to perform the LDPC decoding on an LDPC codeword formed of 16200 bits based on a parity check matrix, wherein the parity check matrix includes an information word sub-matrix and a parity sub-matrix, and wherein the information word sub-matrix has a plurality of column groups each including 360 columns and being defined as a table indicating positions of one (1) present in each 360-th column.

The LDPC decoder may perform the LDPC decoding using a parity check matrix defined as a table such as Table 6 when the code rate is 7/15.

The LDPC decoder may perform the LDPC decoding using a parity check matrix defined as a table such as Table 10 when the code rate is 5/15.

The LDPC decoder may perform the LDPC decoding using a parity check matrix defined as a table such as Table 11 when the code rate is 9/15.

The LDPC decoder may perform the LDPC decoding using a parity check matrix defined as a table such as Table 14 when the code rate is 11/15.

The LDPC decoder may perform the LDPC decoding using a parity check matrix defined as a table such as Table 14 when the code rate is 13/15.

According to yet still another aspect of the present invention, a decoding method for performing LDPC decoding includes: performing the LDPC decoding on an LDPC codeword formed of 16200 bits based on a parity check matrix, wherein the parity check matrix includes an information word sub-matrix and a parity sub- matrix, and wherein the information word sub-matrix comprises a plurality of column groups each including 360 columns and being defined as a table indicating positions of one (1) present in each 360-th column.

In the performing of the LDPC decoding, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 6 when the code rate is 7/15.

In the performing of the LDPC decoding, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 10 when the code rate is 5/15.

In the performing of the LDPC decoding, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 11 when the code rate is 9/15.

In the performing of the LDPC decoding, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 13 when the code rate is 11/15.

In the performing of the LDPC decoding, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 14 when the code rate is 13/15. [Advantageous Effects]

According to the above-described various exemplary embodiments, LDPC encryption and decryption performance can be improved.

Additional and/or other aspects and advantages of the exemplary embodiments will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of these embodiments.

[Description of Drawings]

The above and/or other aspects of the inventive concept will be more apparent by describing certain exemplary embodiments with reference to the accompanying drawings, in which:

FIG. 1 is a diagram showing a codeword of a systematic low density parity check (LDPC) code;

FIG. 2 is a diagram showing a parity check matrix and a factor graph of a general (8, 2, 4) LDPC code;

FIG. 3 is a diagram showing a parity check matrix according to an exemplary embodiment;

FIGs. 4A and 4B illustrate a check node and a variable node used for LDPC decoding, according to exemplary embodiments;

FIG. 5 is a block diagram for describing a configuration of an encoding apparatus according to an exemplary embodiment;

FIG. 6 is a block diagram for describing a configuration of a transmitting apparatus according to an exemplary embodiment;

FIG. 7 is a block diagram for describing a configuration of a decoding apparatus according to an exemplary embodiment;

FIG. 8 is a block diagram for describing a decoding apparatus according to an exemplary embodiment; FIG. 9 is a block diagram for describing a configuration of a receiving apparatus according to an exemplary embodiment;

FIG. 10 is a flow chart for describing an encoding method according to an exemplary embodiment; and FIG. 11 is a flow chart for describing a decoding method according to an exemplary embodiment.

[Best Mode] [Mode for Invention]

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. Further, when it is determined that the detailed descriptions of the known function or configuration related to the exemplary embodiments may obscure the gist of the inventive concept, the detailed descriptions thereof will be omitted.

Hereinafter, low density parity check (LDPC) encoding and decoding technologies in a communication/broadcasting system according to exemplary embodiments will be described.

In the following exemplary embodiments, terms and names defined in the Digital Video Broadcasting the Second Generation Terrestrial (DVB-T2) system, which is one of the European digital broadcasting standards, and a North America digital broadcasting standard system (Advanced Television Systems Committee (ATSC) 3.0) will be used. However, the inventive concept is not limited to these terms and names, but may be similarly applied to other systems.

A graph representation method of an LDPC code will be described with reference to FIG. 2.

FIG. 2 is a diagram showing an example of a parity check matrix Hj of an LDPC code configured of four (4) rows and eight (8) columns and a Tanner graph thereof. Referring to FIG. 2, since the parity check matrix Hj has eight (8) columns, it generates a codeword having a length of eight (8), a code generated through Hi means an LDPC code, and each column corresponds to encoded eight (8) bits.

Referring to FIG. 2, a Tanner graph of the LDPC code encoded and decoded based on the parity check matrix Hj is configured of eight (8) variable nodes, that is, Xi(202), x₂(204), x₃(206), x„(208), x₅(210), x₅(212), x₇(214) and xg(216) and four (4) check nodes 218, 220, 222 and 224. Here, an i-th column and a j-th row of the parity check matrix Hi of the LDPC code correspond to a variable node x; and a j-th check node, respectively. In addition, the meaning of a value one (1) (that is, a value that is not zero (0)) of a point at which a j-th column and j-th row of the parity check matrix Hi of the LDPC code intersect with each other is that an edge connecting the variable node ¾ and the j-th check node to each other is present on the Tanner graph as shown in FIG. 2. Degrees of variable nodes and check nodes in the Tanner graph of the LDPC code mean the number of edges connected to the respective nodes, which is the number of entries that are not zero (0) in a column or a row corresponding to a corresponding node in the parity check matrix of the LDPC code. For example, in FIG. 2, degrees of the variable nodes Xi(202), x₂(204), x₃(206), x₄(208), x₅(210), x₆(212), x₇(214) and x₈(216) are sequentially 4, 3, 3, 3, 2, 2, 2 and 2, respectively, and degrees of the check nodes 218, 220, 222 and 224 are sequentially 6, 5, 5 and 5, respectively. In addition, the numbers of entries that are not zero (0) in the respective columns of the parity check matrix Hi of FIG. 2 corresponding to the variable nodes of FIG. 2 sequentially coincide with the above-mentioned degrees 4, 3, 3, 3, 2, 2, 2 and 2, and the numbers of entries that are not zero (0) in the respective rows of the parity check matrix Hi of FIG. 2 corresponding to the check nodes of FIG. 2 sequentially coincide with the above-mentioned degrees 6, 5, 5 and 5.

As described above, an i-th bit c, of the LDPC codeword is associated with an i-th column of the parity check matrix and corresponds to an i-th variable node of the Tanner graph. Therefore, performance of the i-th bit may be determined depending on positions and the number of ones (Is) in the i-th column of the parity check matrix. Therefore, performance of N|_dpc codeword bits of the codeword depends on the positions and the number of ones (Is) in the parity check matrix.

Hereinafter, a feature of a parity check matrix of an LDPC code having a specific structure will be described with reference to FIG. 3.

According to an exemplary embodiment, a parity check matrix having a structure as shown in FIG. 3 will be considered. The parity check matrix shown in FIG. 3 has a systematic structure in which a codeword includes an information word as it is. Hereinafter, although the inventive concept will be described based on a parity check matrix of FIG. 3, an applicable range of the inventive concept is not limited to the parity check matrix as shown in FIG. 3.

In FIG. 3, N_ldpc means a length of an LDPC codeword, and K|_dpc means a length of an information word. The length of the codeword or the information word means the number of bits included in the codeword or the information word. M is an interval at which patterns of columns in a sub-matrix 310 (hereinafter, referred to as an information word sub-matrix) corresponding to the information word are repeated, and Qi_dpc is a magnitude at which each column in the information word sub-matrix 310 is cyclically shifted. Values of the integers M and Q_ldpc are determined to satisfy an equation: Qi_dpc = ( i_dpc - K|_dpc)/ . Here, Ki_dpc/M is also an integer. Values of M and Qi_dpc may be changed depending on a length and a code rate (or coding rate) of the codeword.

Referring to FIG. 3, the parity check matrix 300 is divided into the information word sub-matrix 310 and a sub-matrix 320 (hereinafter, referred to as a parity sub-matrix) corresponding to a parity. The information word sub-matrix 310 includes Ki_dpc columns, and the parity sub-matrix 320 includes N_parity = N_ldpc - Ki_dpc columns. The number of rows of the parity check matrix 300 is the same as that (Ni_dpc - K|_dpc) of columns of the parity sub- matrix 320.

In the parity sub-matrix 320 including a K_]dpc-th column to an Ni_dpc-l-th column of the parity check matrix 300, positions of entries having a weight-1, that is, a value of one (1), have a dual diagonal structure. Therefore, all of degrees (here, the degree is the number of ones (Is) included in each column) of columns other than the (Ni_dpc-l)-th column among columns included in the parity sub-matrix 320 are two (2), and a degree of the (N_ldpc- l)-th column is one (1).

Referring to FIG. 3, a structure of the information word sub-matrix 310, that is, a sub-matrix including a zero (0)-th column to a (Ki_dpc-l)-th column, in the parity check matrix 300 follows the following rules.

First, K_ldpc columns corresponding to the information word in the parity check matrix 300 belong to a plurality of column groups or blocks each having M columns, and are divided into a total of K_ldpc M column groups. Columns belonging to the same column group have a relationship in which they are shifted from a previous column by Qi_dpc.

Second, when it is assumed that a degree of a zero (0)-th column of an i-th (i=0, 1, .. , Ki_dpc/M - 1) column group is Dj and positions of the respective rows at which one (1) is present are *Ό ' *.0 ' * *>0 , JC_tJ

an index of a row at which a weight-1 is positioned in a j-th column within the i-th column group is determined as represented by following mathematical expression 2.

^Q l<¾>c >^mOd(N|_dp_C-K|_dpc)

... (2),

where k=0, 1, 2, ... , D_rl, i = 0, 1, ... ,K_ldpc/M - 1, and j = 1, 2, ... ,M - 1. Meanwhile, above mathematical expression 2 may be represented by the following mathematical expression

3.

where k = 0, 1, 2, ... , D_rl, i = 0, 1, ... , K _ipJM - 1, and j = 1, 2, ... , M - 1.

In the above mathematical expressions, means an index of a row at which a k-th weight-1 is present in the j-th column within the i-th column group, N_ldpc means a length of the LDPC codeword, K_ldpc means a length of the information word, Dj means a degree of columns belonging to the i-th column group, and M means the number of columns belonging to one column group.

According to these mathematical expressions, when only a value of *·° is recognized, an index of a row at which the k-th weight-1 is present within the i-th column group may be recognized. Therefore, when an index values of a row at which the k-th weight-1 is present in a zero (0)-th column within each column group is stored, positions of a column and a row at which the weight-1 is present in the parity check matrix 300 (that is, the information word sub-matrix 310 of the parity check matrix 300) having the structure shown in FIG. 3 may be recognized.

According to the above-mentioned rules, all of the degrees of the columns belonging to the i-th column group are the same D;. Meanwhile, according to the above-mentioned rules, the LDPC code in which information on the parity check matrix 300 is stored may be simply represented as follows.

As a specific example, in the case in which N_ldpc is 30, K|_dpc is 15, and Q_ldpc is three (3), information on positions of rows at which the weight-1 is positioned in zero (0)-th columns within three column groups may be represented by sequences as represented by following mathematical expression 4. The sequences as represented by following mathematical expression 4 may be called a weight-1 position sequence.

y$ =¾i$ = 8^ = 10,

J¾ = 0,^ =9,^ = 13, » (*)

In above mathematical expression 4, means an index of a row at which the k-th weight-1 is present in the j-th column within the i-th column group.

The weight-1 position sequences as represented by above mathematical expression 4, which indicates indices of the rows at which one (1) is positioned in the zero (0)-th columns of the respective column groups, may be more simply represented by following Table 1.

Table 1]

In Table 1 showing positions of entries having a weight-1, that is, a value of one (1), in the parity check matrix, an i-th weight-1 position sequence may be represented by indices of rows at which the weight-1 is present in the zero (0)-th column belonging to the i-th column group.

The LDPC code suggested in the present embodiment is characterized in that it is grouped in a unit of M columns in the parity check matrix as described above to have a specific form. One column group configured of M columns in the parity check matrix 300 corresponds to an information bit group 340 of the information word in the codeword 330 of FIG. 3 having M bits. In other words, a term 'column group' used in the present embodiment means that grouping was performed on the parity check matrix, and a term 'bit group' means that grouping was performed on the codeword. In addition, it is to be noted that the column group and the bit group have a one-to-one corresponding relationship therebetween.

Performance of the LDPC code may be changed depending on the positions and the number of the weight-Is configuring the parity check matrix. In other words, when it is assumed that a size of the parity check matrix is determined for a given codeword length, a code rate, and the like, the performance of the LDPC code may be changed depending on the positions and the number of the weight-Is configuring the parity check matrix. In addition, the number of weight-Is is closely related to complexity of encoding and decoding of the LDPC code. Therefore, in the case in which the size of a parity check matrix is determined for a given codeword length, code rate, and the like, it is an important process in designing an excellent LDPC code to appropriately determine the number and the positions of weight-Is.

In the present embodiment, a design method of an LDPC code grouped in a unit of M columns as shown in FIG. 3 is suggested, and encoding and decoding apparatuses using the LDPC code designed by this method are suggested.

The following conceptually and sequentially shows a process for a design method of an LDPC code according to an exemplary embodiment.

Step 1) a size (Ν_ωρς, Κ_ωρς) of a parity check matrix to be designed and a value of M (or Qi_dpc) are determined. It means that the parity check matrix is configured of Ni_dpc columns and N_Mpc - K_:dpc rows. In addition, it is to be noted that a structure of the parity check matrix to be designed should be the same as that of the parity check matrix 300 of FIG. 3. For example, the parity check matrix has a staircase structure in which degrees of N|_dpc - K_ldpc - 1 columns are two (2) and a degree of one column is one (1), as in the parity sub-matrix 320 of the parity check matrix 300 of FIG. 3.

Step 2) a size and a structure of a mother matrix (or mother parity check matrix) for designing the parity check matrix having the size determined in Step 1 are set. A size of the mother matrix is configured of N_]dpc M columns and (N_Mpc - K_ldpc)/M rows, and a parity portion has the same structure as that of the parity check matrix 300 of FIG. 3. That is, the parity portion has a staircase structure in which degrees of N|_dpc - K|_dpc - 1 columns are two (2) and a degree of one column is one (1), as in the parity sub-matrix 320 of the parity check matrix 300 of FIG. 3.

Step 3) an appropriate degree distribution is found in order to design the mother matrix. As a typical method for finding the degree distribution, density evolution (reference: Richardson, T., and URBANKE, R.: The capacity of low-density parity-check codes under message-passing decoding', IEEE Trans. Inf. Theory, 2001, 47, (2), pp. 599-618) may be used. When the degree distribution is found, it is to be noted that the number of columns having a degree of two (2) is fixed to (Ni_dpc - K_)dpc) M - 1 and the number of columns having a degree of one (1) is fixed to one (1). Step 4) the mother matrix is designed so as to satisfy the degree distribution found in Step 3. The mother matrix is designed in consideration of cycle characteristics in an order of low degrees.

Step 5) a final parity check matrix is designed from the mother matrix. As a method of designing the final parity check matrix, a lifting method in which the cycle characteristics are considered from the mother matrix is used.

Hereinafter, the lifting method described in Step 5 will be described in more detail.

The lifting method is a method that may relatively simply generate a parity check matrix having a larger size based on a parity check matrix having a small size. For example, when a parity check matrix Hi including column groups configured in a unit of Mi columns and having a total number of columns corresponding to Ni and the number of rows corresponding to Ni - Ki is given, a parity check matrix H₂ including column groups configured in a unit of M₂ columns and having a total number of columns corresponding to N₂ and the number of rows corresponding to N₂ - K₂ may be obtained by the lifting method.

Here, the following relationship: N2/N1 = (N₂ - K₂)/(Ni - Ki) =

= A (A indicates a positive integer larger than one (1)) is satisfied. Here, it is to be noted that Qi_dpci = ( i - Ki)/Mi = (N₂ - K₂)/M₂ = Qi_dpC2-

Hereinafter, a process of generating the parity check matrix H₂ larger than the given parity check matrix H_: from the parity check matrix Hi by applying the lifting while maintaining the structure of FIG. 3 will be described.

It is assumed that a sequence indicating information on an i-th column group corresponding to an

^ CO) ^ C . .. _R (£>r

information word bit of the given parity check matrix Hi is ≠.0 * i,0 ^{> »} i,0 in order to describe the lifting process. Here, i = 0, 1, ... ,Ki/M] - 1, and Dj means a degree of columns belonging to the i-th column group.

Lifting Step 1) a matrix having the same structure as that of a sub-matrix corresponding to the parity portion of FIG. 3 and having a size of (N₂ - K₂) x (N₂ - K₂) is set to a parity sub-matrix corresponding to a parity portion of H₂.

Step 2) i is initialized to zero (0). Step 3) for each of sequences (k = 0, 1, 2, ... .D, - 1) indicating the information on the i-th column group corresponding to the information word bit of the parity check matrix Hj, a set

configured of A sequences is defined as follows. Here, A is a positive integer satisfying N2/N1 = (N₂ - K₂)/(N_! - Ki) = Μ^ Λι = A.

Step 4) sequences s ^ ^w'⁰ (k = 0, 1, 2, ... , D; - 1) satisfying following <condition 1> and <condition 2> are sequentially found on an assumption that information word column groups corresponding to an (i+l)-th column group to an (N₂ - K₂)/M₂ - 1-th column group are not present for the parity check matrix H₂ to be designed.

<Condition 1>: S ' ^i*k°⁾≡B ' ^(A (k = 0, 1, 2, ... , D, - 1)

<Condition 2>: a sequence in which a value of a girth on a Tanner graph is maximum and the number of cycles having a corresponding girth is minimum among sequences satisfying <Condition 1>. Here, the girth means a length of the shortest cycle among cycles present on the Tanner graph. However, when the best cases are several, one of them is arbitrarily selected.

Step 5) processes of Step 3 and Step 4 are continuously repeated for i 1, 2, ... ,(N₂ - K₂)/M₂ - 1.

_C (*>

Step 6) a finally selected sequence · (i = 0, 1, ... , K,_dpc/M - 1, k = 0, 1, 2, Dj - 1) is determined to be a sequence indicating a column group corresponding to an information word bit of H₂.

When the lifting method as described above is used, it may become relatively simple to design a parity check matrix configured of Ni_dpc columns and N|_dpc - Ki_dpc rows and including a parity portion having the same structure as that of the parity check matrix 300 of FIG. 3 from a mother parity check matrix configured of N|_dpc/M columns and (N_ldpc - Ki_dpc)/M rows and including a parity portion having the same structure as that of the parity check matrix 300 of FIG. 3

When a parity check matrix is to be designed by applying the lifting for the given mother parity check matrix once, since the numbers of columns and rows of the mother matrix are 1/M of the size of the parity check matrix that is to be finally designed, respectively, a total number of selections of the respective figures s * ^m*° configuring a sequence that is to be found in the lifting process is M. As described above, when the M selections for all of the respective figures indicating the column group corresponding to the information word bit are present, a design is not easy due to an excessive many number when M is relatively large.

However, in the case in which a parity check matrix is designed by applying the lifting in several steps for the given mother matrix, the parity check matrix may be more easily designed. For example, when the mother parity check matrix is ¾ and the parity check matrix that is to be finally designed is H, assume that the lifting was designed through w steps such as H₁→H₂→... -» H_» -» H.

Here, when a size of the column group configuring each parity check matrix H; is M;, it may be appreciated that the following relationship: M₂ = Ai x Mi, M₃ = A₂ x M₂,..., M_w = A_(W_i₎ x M_(w.i₎, M = A_w x M_w is satisfied by the assumption of the lifting process. Here, A; is a positive integer larger than 1 (i = 1,2,...,w). In addition, when the above Equation is arranged, it may be easily confirmed that M = M₁ x A₁ x A₂ x ... x A_w.

In summary, since the number of selections of the respective figures of a sequence indicating the column group of the information word bit in each i-th lifting process is A_i; it may be appreciated that when the lifting is applied w times in order to design H from Hi, a total number of selections is (Ai + A₂ + ... + A_w). This is significantly decreased as compared with the M selections, that is, A] x A₂ x ... x A_w selections when the lifting is applied only once. It may be appreciated that the more the lifting applying steps, the more efficient.

However, in the case in which excessively many lifting steps are applied, the number of selections is excessively decreased, such that it is difficult to find a sequence of column groups having good cycle characteristics. Therefore, the lifting steps may be appropriately selected depending on a code that is to be designed.

As an example of a design result by the above-mentioned method, in the case in which a length N_Mpc of the codeword is 16200, a code rate is 7/15, and M is 360 (or Qi_dpc = 24), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 2.

[Table 2]

As another example, in the case in which a length Ν_ωρ0 of the codeword is 16200, a code rate is 9/15, and M is 360 (or Q|_dpc = 18), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 3.

[Table 3]

As still another example, in the case in which a length N|_dpc of the codeword is 16200, a code rate is 11/15, and M is 360 (or Qi_dpc = 12), indices of rows at which one (1) is positioned in the zero (O)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 4.

[Table 4]

As yet still another example, in the case in which a length N_ldpc of the codeword is 16200, a code rate is 13/15, and M is 360 (or Q_]dpc = 6), indices of rows at which one (1) is positioned in the zero (O)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 5.

[Table 5]

Meanwhile, in the design process of an LDPC code, in Step 5), the lifting method in which the cycle characteristics are considered was applied. When various algebraic characteristics as well as the cycle characteristics are additionally considered, a code having better performance may be designed.

Generally, since the performance of an LDPC code has an influence on the degree distribution as well as the cycle characteristics, a code having better performance may be designed in consideration of both of these two characteristics. In the present embodiment, a method applied to a process of determining a parameter depending on cycles having the shortest length and the number of variable nodes included in these cycles and having a specific degree and determining the sequence in Lift Step 4) depending on a rule determined through the parameter is suggested.

As an example of the present embodiment, <Condition 2> of the Lifting Step 4) is changed into <Condition 2'> and <Condition 3>.

<Condition 2'>: a sequence in which a girth is maximum for cycles satisfying the following <Condition 3> and the number of cycles having the corresponding girth value is minimum among sequences satisfying <Condition 1>.

<Condition 3>: cycles considered in the case in which the lifting process is applied to column groups having degrees of A and B are as follows:

- cycles in which the number of variable nodes having a degree of A among variable nodes included in the cycles in a process of performing lifting of a column group having a degree of A is Xj or less, and

- cycles in which a value of (the number of variable nodes having a degree of A + the number of variable nodes having a degree of B x C) for variable nodes included in the cycles in a process of performing lifting of a column group having a degree of B is X2 or less.

However, all cycles are considered in the case in which the lifting process is applied to column groups of which degrees are not A and B.

Here, A is a positive integer of two (2) or more, B is a positive integer larger than A and smaller than a maximum degree of the parity check matrix, and C, which is a weighting factor, has a positive integer value.

In addition, all cycles are considered without distinction of a specific cycle in the case in which the lifting process is applied to the column groups of which degrees are not A and B.

As a specific example, the case in which A = 3, B = 4, and C = 2 will be described.

For example, in the lifting process, the lifting is performed in consideration of only cycles in which the number of variable nodes (which is the same as that of columns) having a degree of three (3) among variable nodes included in the cycles in a process of performing the lifting of column groups having a degree of three (3) is X] or less and (the number of variable nodes having a degree of four (4) + the number of variable nodes having a degree of three (3)) among variable nodes included in the cycles in a process of performing the lifting of column groups having a degree of four (4) is x₂ or less.

Generally, in simple lifting, the parity check matrix is designed such that the number of cycles is decreased. In this process, the parity check matrix is designed such that the number of cycles satisfying the above- mentioned conditions is decreased.

The reason why the above-mentioned conditions have an influence on designing the LDPC code having a better performance is that the cycles and the degree distribution, which have an influence on the LDPC code, have been considered in the above-mentioned conditions.

Examples of an LDPC code designed in consideration of these additional conditions are shown in following Tables 6 to 15.

For reference, (x_1; x₂) considered in Table 6 is (4, 5), (x x₂) considered in Table 7 is (4, 5), (x_1; x₂) considered in Table 8 is (3, 4), and (xi, x₂) considered in Table 9 is (3, 4).

In addition, (x_1; x₂) considered in Table 10 is (5, 5), (x_1; x₂) considered in each of Tables 11 to 13 is (4, 4), and (x₁₍ x₂) considered in each of Tables 14 and 15 is (3, 4).

Referring to Tables 6 to 15, it may be appreciated that different LDPC codes may be designed for the same Xi and x₂ values. It is to be noted that the reason is that a plurality of selections are possible in selecting the sequence in the lifting process.

As an example of a design result in consideration of the additional conditions as described above, in the case in which a length N_ldpc of the codeword is 16200, a code rate is 7/15, and M is 360 (or Q|_dpc = 24), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 6.

[Table 6]

As another example of the design result in consideration of the additional conditions, in the case in which a length Ni_dpc of the codeword is 16200, a code rate is 9/15, and M is 360 (or Q|_dpc = 18), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 7.

[Table 7]

As still another example of the design result in consideration of the additional conditions, in the case in which a length N_ldpc of the codeword is 16200, a code rate is 11/15, and M is 360 (or Q|_dpc = 12), indices of rows at which one (1) is positioned in the zero (O)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 8.

[Table 8]

As yet still another example of the design result in consideration of the additional conditions, in the case in which N_ldpg is 16200, a code rate is 13/15, and M is 360 (or Q|_dpc = 6), indices of rows at which one (1) is positioned in the zero (O)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by the following Table 9. [Table 9]

As yet still another example of the design result in consideration of the additional conditions, in the case in which N_ldpc is 16200, a code rate is 5/15, and M is 360 (or Q_ldpc = 30), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 10. Table 10]

As yet still another example of the design result in consideration of the additional conditions, in the case in which Ni_dpc is 16200, a code rate is 9/15, and M is 360 (or Q_ldpc = 18), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Tables 11 and 12.

[Table 11]

[Table 12]

As yet still another example of the design result in consideration of the additional conditions, in the case in which N_ldpc is 16200, a code rate is 11/15, and M is 360 (or Q|_dpc = 12), indices of rows at which one (1) is positioned in the zero (O)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Table 13.

[Table 13]

As yet still another example of the design result in consideration of the additional conditions, in the case in which N|_dpc is 16200, a code rate is 13/15, and M is 360 (or Q_ldpc = 6), indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group of the parity check matrix having the structure of FIG. 3 are shown by following Tables 14 and 15. [Table 14]

[Table 15]

Here, it is to be noted that even if a parity-check matrix is changed such that orders of indices within sequences of each i-th column group in Tables 2 to 15 are changed, the changed parity-check matrix is a parity check matrix of the same code.

For example, a sequence corresponding to a zero (0)-th column group in Table 5 is arranged in an order of 380, 671, 699, 745, 1410, 1564. Even if an arranging order of this sequence is changed into 671, 699, 1410, 380, 1564, 745, it is a parity check matrix of the same code. In addition, even if arranging orders of sequences of respective column groups in Tables 2 to 15 are changed, algebraic characteristics such as cycle characteristics, degree distribution, a minimum distance, and the like, on a graph of a code are not changed. Therefore, the case in which arranging orders of sequences shown in Tables 2 to 15 are changed may become one example of a result that may be derived through a code design method suggested in the present embodiment.

For example, even if arranging orders of the sequence 380, 671, 699, 745, 1410, 1564 of a zero (0)-th column group in Table 5 and a sequence 893, 1305, 2030 of a twelfth column group in Table 5 are changed to set the sequence of the zero (0)-th column group to 893, 1305, 2030 and set the sequence of the twelfth column group to 380, 671, 699, 745, 1410, 1564, cycle characteristics, degree distribution, a minimum distance, and the like, on a graph of the code are not changed (actually, since changing arranging orders of sequences of the respective column groups are the same as changing arranging orders of column groups within a parity check matrix, main algebraic characteristics are not changed).

In addition, a result of adding an integer multiple of Q|_dpc to all of the sequences of any column groups in Tables 2 to 15 may also become one example of a result that may be derived through the code design method suggested in the present embodiment since the algebraic characteristics such as the cycle characteristics, the degree distribution, or the like, on the graph of the code are not changed.

For example, as a result of adding a multiple of 6 to all indices 893, 1305, 2030 of the twelfth column group in Table 5 for Qi_dpc = N_ldpc - K_ldpc)/M = 6, also in the case of 899 (= 893 + 6), 1311 (= 1305 + 6), 2036 (= 2030 + 6) or 911 (= 893 + 6 x 3), 1323 (= 1305 + 6 x 3), 2048 (= 2030 + 6 x 3) as a specific example, the algebraic characteristics such as the cycle characteristics, the degree distribution, the minimum distance, or the like, on the graph of the code are not changed (actually, since a sequence obtained as a result of adding a multiple of Qi_dpc to any sequence is a sequence in which only an order of columns present within a corresponding column group is rearranged, main algebraic characteristics are not changed).

Here, it is to be noted that in the case in which a value obtained by adding the multiple of Q_ldpc to a given sequence is a value of (N_ldpc - Ki_dpc) or more, it is changed into a value obtained by applying a modulo operation for (N_]dpc - K_:dpc) to the value. For example, when 6 x 3 is added to all of a sequence 247, 328, 1778, 2040, 2051, 2151 of a second column group in Table 5, a sequence 265, 346, 1796, 2058, 2069, 2169 is resultantly generated. In this case, since (N|_dpc - Ki_dpc) = 2160, modulo-2160 is applied to the sequence, thereby making it possible to represent the sequence as 265, 346, 1796, 2058, 2069, 9 or 9, 265, 346, 1796, 2058, 2069.

In addition, although the sequences are represented based on the structure of the parity check matrix of FIG. 3 in Tables 2 to 15, in the case of applying row permutation for rearranging an order of rows, column permutation for rearranging an order of columns, or the like, to the parity check matrix of FIG. 3, the parity check matrix may be represented in a form different from the structure of FIG. 3. However, since an operation such as the row permutation, the column permutation, and the like, does not change the algebraic characteristics of the LDPC code itself such as the cycle characteristics, the degree distribution, the minimum distance, or the like, the parity check matrices may be considered to be the same as each other.

That is, when any given parity check matrix may be changed into a parity check matrix having the structure as shown in FIG. 3 through appropriate row permutation and column permutation and the case in which sequences coincide with one another in Tables 2 to 15 when the changed parity check matrix is represented like the sequences represented in Tables 2 to 15 is present, it is decided that two parity check matrices are algebraically equivalent to each other.

Hereinafter, a process of encoding an LDPC code using a parity check matrix having the structure as shown in FIG. 3 will be described. As described above, the process of encoding an LDPC code is to determine a codeword satisfying a relational equation: parity check matrix x codeword = 0. That is, the LDPC encoding process may be represented by H · C^T=0. Here, H is a parity check matrix, and C is a LDPC codeword.

Hereinafter, when it is assumed that LDPC encoded information word bits are (½, i], ... , ^ ) and

LDPC codeword bits generated by LDPC encoding are (CQ, c_1; ... , '** ), a method for calculating LDPC codeword bits will be described.

First, since the LDPC code is a systematic code, c_k (0 < k < Ki_dpc - 1) is set to be the same as i_k. In addition, remaining codeword bits are set to **" . Here, p_k indicates parity bits and may be calculated as described below. Meanwhile, since the parity check matrix is defined as in Tables 2 to 15 according to an exemplary embodiment, a process to be described below may be applied in the case in which the parity check matrix is defined as in Tables 2 to 15.

First, when it is assumed that an entry denoted in a j-th position of an i-th row in Tables 2 to 15 is q (i, j, 0), q (i, j, 1) = q (i, j, 0) + Qi_dpc " 1 (mod Ν_ωρο - K_Mpc) for 0 < 1 < 360. Here, accumulation '+' means additions defined in a Galois field (GF) (2) (that is, additions in GF(2)). In addition, Q_ldpc, which is a magnitude at which each column is cyclically shifted in an information word sub-matrix, may be a value defined in each of Tables 2 to 15.

Meanwhile, when q (i, j, 0) and q (i, j, 1) are defined as described above, a process of calculating parity bits is as follows.

Step 1) parity bits are initialized to Ό'. That is, p_k = 0 for 0< k <N_ldpc - K_ldpc i := LM360j

Step 2) i and 1 are set so that and 1: = k (mod 360) for all k values of 0< k <K_ldpc. Here,

W Li .2j=i

is the largest integer value among integers that are not larger than x. That is, . Then, i_k is added to p_q(i,j, i) for all js as follows based on the set i and j values. That is, p_q (i,o, i) = Pq (i, o, i) ⁺ ik_> Pq(u, = Ρς ρ, ι, ΐ) + ik> Pq (i, 2, i) = Pq (i, 2, 1) + h,--, Pq (i, w(i) - i, i) = Pq (i, w(i) -i, l) + ik are calculated.

Here, w(i) is the number of values of the i-th row in Tables 2 to 15 and means the number of ones (Is) of a column corresponding to i_k in the parity check matrix. That is, w(i) means the number of ones (Is) of the column corresponding to i_k in the parity check matrix. In addition, q (i, j, 0), which is an entry denoted in a j-th position of an i-th row in Tables 2 to 15, is an index of the parity bit, and indicates a position of a row at which one (1) is present in a column corresponding to i* in the parity check matrix.

Step 3) P_k = P_k+ p_k-i is calculated for all ks satisfying 0< k <N,_dpc - K_ldpc to calculate the parity bit p_k.

The parity bits are calculated by the above-mentioned method. As a result, the LDPC codeword bits c¾, c N -1

Ci, ... , '** may be calculated. Meanwhile, the LDPC encoding process as described above is only an example. Meanwhile, since the LDPC encoding is a process of calculating an LDPC codeword C satisfying H · C^T=0, various encoding methods may be present for the given parity check matrix.

For example, a scheme applied in a DVB-T2 standard may also be applied to the case in which the parity check matrix is defined as shown in Tables 2 to 15. Hereinafter, the LDPC encoding process depending on the scheme applied in the DVB-T2 standard will be schematically described using an example in which the parity check matrix is defined as in Table 5.

First, when it is assumed that information word bits having a length of K,_dpc are

W and parity bits having a length of N_ldpc - K_:dpc are upe tire ^ _tne Lope encoding may be performed b the following process. Step 1) parity bits are initialized to Ό'. That is,

Step 2) zero (0)-th information word bits io are accumulated in parity bits having addresses of parity bits defined in a first row (that is, a row of i = 0) of Table 5 as indices of the parity bits. This may be represented by following mathematical expression 5.

^Ρ380 ^{= Ρ}380 © 'θ

Ρ671 ^{= Ρ}671 © 'θ

Ρ699 ^{= Ρ}699 © 'θ

745 ^{= P}745 © '0

P1410 ^{= P}1410 © '0

P1564 ^{= P}1564 © '0

... (5), where i₀ means a zero (0)-th information word bit, j means an i-th parity bit, and means a binary operation. According to the binary operation, 1 ® 1 is 0, 1 ® 0 is 1, 0® 1 is 1, and 0® 0 is 0.

Step 3) 359 remaining information word bits i_m (m = 1, 2, ... ,359) are accumulated in the parity bits. Here, the remaining information word bits may be information word bits belonging to the same column group as a column group to which io belongs. Here, an address of the parity bit may be determined based on following mathematical expression 6.

(*+Omod360) x Q^modi N^- K^) ^

Here, x is an address of a parity bit accumulator corresponding to the information word bit ½, and Q_idpc, which is a size at which each column is shifted in a sub-matrix corresponding to the information word, is 6.

As a result, each of the information word bits i_m (m = 1, 2, ... , 359) are accumulated in each of the parity bits having the addresses of the parity bits calculated based on above mathematical expression 6 as indices. As an example, an operation as represented by following mathematical expression 7 may be performed on the information word bit ij.

^P386 ⁼ ^Ρ386 ® ίΐ

^P677 ⁼ ^P677 ® 'l

^P705 ⁼ ^05© * !

^P1416 ⁼ = Ρ₁₄₁₆ θ ϊ

^P1570 ⁼ ^ΙδΖΟ © ¹

•••(7) where i] means a 1-th information word bit, p_f means an i-th parity bit, and ® means a binary operation.

According to the binary operation, 1 ® 1 is 0, 1 ® 0 is 1, 0 ® 1 is 1, and 0 ® 0 is 0.

Step 4) 360-th information word bits i₃₆o are accumulated in parity bits having addresses of parity bits defined in a second row (that is, a row of i = 1) of Table 5 as indices of the parity bits.

Step 5) 359 remaining information word bits belonging to the same group as a group to which the information word bits i₃₆₀ belong are accumulated in the parity bits. Here, an address of the parity bit may be determined based on above mathematical expression 6. However, in this case, x is an address of a parity bit accumulator corresponding to the information word bits i₃₆₀.

Step 6) the processes of Step 4 and Step 5 are repeated for all of the column groups of Table 5.

Step 7) as a result, the parity bit p_f is calculated based on following mathematical expression 8. Here, i is initialized to one (1).

In above mathematical expression 8, p; means is an i-th parity bit, N_ldpc means a length of the LDPC codeword, Ki_dpc means a length of the information word in the LDPC codeword, and means a binary ffs da d¾ ff₎

operation According to the binary operation, 1 ^ 1 is 0, 1 0 is 1, 0 ^W 1 is 1, and O ^^7' 0 is 0.

As a result, the parity bits may be calculated in the above-mentioned scheme.

Meanwhile, an address of a parity bit appearing in a zero (0)-th column of an i-th column group is the same as an index of a row at which one (1) is positioned in the zero (0)-th column of the i-th column group. Therefore, indices of rows at which one (1) is positioned in an i-th column of a zero (0)-th column group of Tables 2 to 15 may be represented as addresses of the parity bits in the encoding process. Therefore, Tables 2 to 15 may mean "addresses of parity bit accumulators".

As described above, in the present embodiment, the LDPC encoding process is performed in various schemes, thereby making it possible to generate the LDPC codeword.

Meanwhile, the LDPC code may be decoded using an iterative decoding algorithm based on a sum-product algorithm on a bipartite graph arranged in FIG. 2. Here, the sum-product algorithm is a kind of message passing algorithm, which is an algorithm exchanging messages through edges on the bipartite graph and calculating and updating an output message from messages input to variable nodes or check nodes.

Hereinafter, a message passing operation generally used in at the time of LDPC decoding will be described with reference to FIG. 4, according to an exemplary embodiment.

FIGs. 4A and 4B illustrate a message passing operation in any check node and any variable node for LDPC decoding.

FIG. 4A illustrates a message passing operation in any check node and any variable node of an LDPC decoding apparatus.

In FIG. 4A, a check node m 400 and a plurality of variable nodes 410, 420, 430 and 440 connected to the check node m 400 are shown. In addition, Τ_η·_>π1 shown in FIG. 4A indicates a message passing from the variable node n' 410 to the check node m 400, and E_n>m indicates a message passing from the check node m 400 to the variable node n 430. Here, a set of all variable nodes connected to the check node m 400 is defined as N(m), and a set except for the variable node n 430 in N(m) is defined as N(m) \ n.

In this case, a message update rule based on the sum-product algorithm may be represented by following mathematical expressions 9. ti'€N(m) \n

Sign(E_n„)= _n,_e n_{m) i} sign(T„,_J,) ^ where Sign(E_{n m}) indicates a sign of the message E_n,m, and E_{n m} indicates a magnitude of the message E_{n m}.

Meanwhile, a function Φ(χ ') may be represented by following mathematical expression 10.

Meanwhile, in FIG. 4B, a variable node x 450 and a plurality of check nodes 460, 470, 480 and 490 connected to the variable node 450 are shown. In addition, E_y ^ shown in FIG. 4B indicates a message passing from the check node y' 460 to the variable node x 450, and T_{y x} indicates a message passing from the variable node x 450 to the variable node y 480. Here, a set of all variable nodes connected to the variable node x 450 is defined as M(x), and a set except for the check node y 480 in M(x) is defined as M(x) \ y. In this case, a message update rule based on the sum-product algorithm may be represented by following mathematical expression 11.

Here, E_x means an initial message value of the variable node x.

In addition, in the case in which a bit value of the node x is determined, it may be represented by following mathematical expression 12.

""W .. (12) In this case, an encoding bit corresponding to the node x may be determined depending on a value of P_x.

Meanwhile, since the decoding method described with reference to FIGs. 4A and 4B is a general decoding method, a detailed description thereof will be omitted. However, a method (Frank R. Kschischang, Brendan J. Frey, and Hans-Andrea Loeliger, "Factor Graphs and the Sum-Product Algorithm," IEEE TRANSACTIONS ON INFORMATION THEORY, VOL. 47, NO. 2, FEBRUARY 2001, pp 498-519) other than the method described with reference to FIG. 4 may be applied in determining a message value passing from the variable node and the check node.

FIG. 5 is a block diagram showing a configuration of an encoding apparatus according to an exemplary embodiment. In this case, the encoding apparatus 500 may perform LDPC encoding described above.

As shown in FIG. 5, the encoding apparatus 500 includes an LDPC encoder 510. The LDPC encoder 510 may perform LDPC encoding on input bits based on a parity check matrix to generate an LDPC codeword. Here, the LDPC codeword may be configured of 16200 bits. That is, a length of the LDPC codeword may be 16200.

Here, the parity check matrix may have the same form as that of the parity check matrix 300 shown in FIG. 3.

In detail, the parity check matrix includes an information word sub-matrix and a parity sub-matrix.

Here, the information word sub-matrix is configured of a plurality of column groups each including M columns and is defined as a table indicating a position of a value of one (1) present in each M-th column. Here, M, which is an interval at which patterns of columns are repeated in the information word sub-matrix, may be 360. In addition, the parity sub-matrix may have a dual diagonal structure.

In this case, the LDPC encoder 510 may perform the LDPC encoding using parity check matrices differently defined depending on a code rate (that is, a code rate of the LDPC code).

For example, the LDPC encoder 510 may perform LDPC encoding using a parity check matrix defined as a table such as Table 2 or Table 6 in the case in which the code rate is 7/15 and perform LDPC encoding using a parity check matrix defined as a table such as Table 3, Table 7, Table 11 or Table 12 in the case in which the code rate is 9/15. In addition, the LDPC encoder 510 may perform LDPC encoding using a parity check matrix defined as a table such as Table 4, Table 8 or Table 13 in the case in which the code rate is 11/15 and perform LDPC encoding using a parity check matrix defined as a table such as Table 5, Table 9, Table 14 or Table 15 in the case in which the code rate is 13/15. In addition, the LDPC encoder 510 may perform LDPC encoding using a parity check matrix defined as a table such as Table 10 in the case in which the code rate is 5/15.

Meanwhile, since a detailed method for performing LDPC encoding has been described above, duplicate descriptions will be omitted.

Meanwhile, the encoding apparatus 500 may further include a memory (not shown) pre-storing information on a code rate, a codeword length, and a parity check matrix of a LDPC code therein, and the LDPC encoder 510 may perform LDPC encoding using this information. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column.

FIG. 6 is a block diagram showing a configuration of a transmitting apparatus according to an exemplary embodiment. As shown in FIG. 6, the transmitting apparatus 600 may include a Bose, Chaudhuri, Hocquenghem (BCH) encoder 610, an LDPC encoder 620, an interleaver 630, and a modulator 640.

The BCH encoder 610 performs BCH encoding on input bits and outputs a BCH codeword generated by the BCH encoding to the LDPC encoder 620.

In detail, the BCH encoder 610 performs the BCH encoding on the input bits

to generate K,_dpc - K_bCh BCH parity bits and generate a BCH codeword

The BCH codeword *^ , which is an information word, for LDPC encoding, is input to the LDPC encoder 620. Since the BCH encoding, which is a well known technology, is disclosed in a document such as "Bose, R. C; Ray-Chaudhuri, D. K. (March 1960), "On A Class of Error Correcting Binary Group Codes", Information and Control 3 (1): 68-79, ISSN 0890-5401", or the like, detailed descriptions thereof will be omitted.

Meanwhile, it may be changed whether or not the BCH encoder 610 is used. That is, in some cases, the BCH encoder 610 may also be omitted. The LDPC encoder 620 performs LDPC encoding on the BCH codeword output from the BCH encoder 610 and outputs the LDPC codeword generated by the LDPC encoding to the interleaver 630.

In detail, the LDPC encoder 620 performs the LDPC encoding on the BCH codeword

^idpc ~ ['o»*l>^* ' " »^■* A" ·- 1 J

output from the BCH encoder 610 so as to be an information word to generate N|_dpc - K_Mpc LDPC parity bits and generate the LDPC codeword

However, in the case in which the BCH encoder 610 is omitted, the LDPC encoder 620 may perform the LDPC encoding on the input bits.

Meanwhile, the LDPC encoder 620 of FIG. 6 may be implemented by the LDPC encoder 510 described with reference to FIG. 5. That is, the LDPC encoder 620 may perform the LDPC encoding using a parity check matrix including an information word sub-matrix defined depending on a code rate as shown in Tables 2 to 15 and a parity sub-matrix having a dual diagonal structure.

To this end, the transmitting apparatus 600 may include a memory (not shown) storing information on the parity check matrix therein. In this case, the parity check matrix may have various forms depending on the code rate, and the tables defined in Tables 2 to 15 may be an example. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column.

The interleaver 630 performs interleaving on the LDPC codeword output from the LDPC encoder 620 and output interleaved bits to the modulator 640.

In this case, the interleaver 630 receives LDPC codeword bits output from the LDPC encoder 620 and perform the interleaving in a predetermined scheme. Various interleaving schemes may be present, and it may be varied whether or not the interleaver 630 is used.

The modulator 640 modulates bits output from the interleaver 630 and transmits the modulated bits to a receiving apparatus (for example, 900 of FIG. 9).

In detail, the modulator 640 may demultiplex the bits output from the interleaver 630 and map the demultiplexed bits to a constellation. That is, the modulator 640 converts bits output from the interleaver 630 in a serial-to-parallel form, thereby making it possible to generate a cell configured of a predetermined number of bits. Here, the number of bits configuring each cell may be the same as that of bits configuring a modulated symbol mapped to the constellation.

Then, the modulator 640 may map the demultiplexed bits to the constellation. That is, the modulator 640 may modulate the demultiplexed bits in various modulation schemes such as quadrature phase shift keying (QPSK), 16-quadrature amplitude modulation (QAM), 64-QAM, 256-QAM, 1024-QAM, and 4096-QAM to generate the modulated symbols and may the modulated symbols to constellation points. In this case, since the demultiplexed bits configure the cell corresponding to the modulated symbol, the respective cells may be sequentially mapped to the constellation points.

In addition, the modulator 640 may modulate a signal mapped to the constellation and transmit the modulated signal to the receiving apparatus 900. For example, the modulator 640 may map the signal mapped to the constellation to an orthogonal frequency division multiplexing (OFDM) frame in an OFDM scheme and transmit the signal to the receiving apparatus 900 through an allocated channel.

Meanwhile, the transmitting apparatus 600 may pre-store various parameters used for the encoding, the interleaving, and the modulation therein. Here, the parameter used for the encoding may be information on a code rate and a codeword length of a BCH code, and a code rate, a codeword length, and a parity check matrix of an LDPC code. In addition, the parameter used for the interleaving may be information on an interleaving rule, and the parameter used for the modulation may be information on a modulation scheme. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column.

In this case, operations of the respective components configuring the transmitting apparatus 600 may be performed using these parameters.

Meanwhile, although not shown, the transmitting apparatus 600 may further include a controller (not shown) for controlling an operation thereof in some cases. In this case, the controller (not shown) may provide the information on the code rate and the codeword length of the BCH code to the BCH encoder 610 and provide the information on the code rate, the codeword length, and the parity check matrix of the LDPC code to the LDPC encoder 620. In addition, the controller (not shown) may provide information on the interleaving scheme to the interleaver 630 and provide information on the modulation scheme to the modulator 640. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column.

FIG. 7 is a block diagram showing a configuration of a decoding apparatus according to an exemplary embodiment. As shown in FIG. 7, the decoding apparatus 700 may include an LDPC decoder 710.

The LDPC decoder 710 may perform LDPC decoding on an LDPC codeword based on the parity check matrix. Here, the LDPC codeword may be configured of 16200 bits. That is, a length of the LDPC codeword may be 16200.

For example, the LDPC decoder 710 may pass a log likelihood ratio (LLR) value corresponding to LDPC codeword bits therethrough by an iterative decoding algorithm to perform the LDPC decoding, thereby generating information word bits.

Here, the LLR value, which is a channel value corresponding to the LDPC codeword bits, may be represented by various methods.

For example, the LLR value may be represented as a log value of a ratio of likelihood that bits transmitted from a transmitting side through a channel will be 0 to likelihood that the bits will be 1. In addition, the LLR value may be a bit value itself determined depending on hard decision or be a representative value determined depending on a section to which likelihood that the bits transmitted from the transmitting side will be 0 or 1 belongs.

In this case, the transmitting side may generate the LDPC codeword using the LDPC encoder 510 as shown in FIG. 5 and transmit the generated LDPC codeword.

Meanwhile, the parity check matrix used at the time of the LDPC decoding may have the same form as that of the parity check matrix 300 shown in FIG. 3. In detail, the parity check matrix may include an information word sub-matrix and a parity sub-matrix.

Here, the information word sub-matrix is configured of a plurality of column groups each including M columns and is defined as a table showing positions of values of 1 present in each M-th column. Here, M, which is an interval between repeated column patterns in the information word sub-matrix, may be 360. In addition, the parity sub-matrix may have a dual diagonal structure.

In this case, the LDPC decoder 710 may perform the LDPC decoding using parity check matrices differently defined depending on a code rate (that is, a code rate of the LDPC code).

For example, the LDPC decoder 710 may perform the LDPC decoding using a parity check matrix defined as a table such as Table 2 or Table 6 in the case in which the code rate is 7/15 and perform the LDPC decoding using a parity check matrix defined as a table such as Table 3, Table 7, Table 11 or Table 12 in the case in which the code rate is 9/15. In addition, the LDPC decoder 710 may perform the LDPC decoding using a parity check matrix defined as a table such as Table 4, Table 8 or Table 13 in the case in which the code rate is 11/15 and perform the LDPC decoding using a parity check matrix defined as a table such as Table 5, Table 9, Table 14 or Table 15 in the case in which the code rate is 13/15. In addition, the LDPC decoder 710 may perform the LDPC decoding using a parity check matrix defined as a table such as Table 10 in the case in which the code rate is 5/15.

Meanwhile, as described above, the LDPC decoder 710 may perform the LDPC decoding using the iterative decoding algorithm. In this case, the LDPC decoder 710 may have a structure as shown in FIG. 8. However, since the iterative decoding algorithm has been already known, a detailed configuration shown in FIG. 8 is only an example.

As shown in FIG. 8, the decoding apparatus 800 includes an input processor 811, a memory 812, a variable node operator 813, a controller 814, a check node operator 815, and an output processor 816.

The input processor 811 stores an input value therein. In detail, the input processor 811 stores an LLR value of a reception signal received through a radio channel.

The controller 814 determines a size of a block of the reception signal received through the radio channel, the number of values input to the variable node operator 813, an address value in the memory 812, the number of values input to the check node operator 815, an address value in the memory 812, and the like, based on a parity check matrix corresponding to a code rate.

According to an exemplary embodiment of the present embodiment, the LDPC decoder 710 may perform decoding based on a parity check matrix having a form of FIG. 3 in which indices of rows at which one (1) is positioned in the zero (0)-th column of the i-th column group are defined as shown in Tables 2 to 15.

The memory 812 stores input data and output data of the variable node operator 813 and the check node operator 815 therein.

The variable node operator 813 receives data from the memory 812 depending on information on an address of the input data and information on the number of input data received from the controller 814 and performs a variable node operation. Then, the variable node operator 813 stores variable node operation results in the memory 812 based on information on an address of the output data and information on the number of output data received from the controller 814. In addition, the variable node operator 813 inputs the variable node operation result to the output processor 816 based on data received from the input processor 811 and the memory 812. Here, the variable node operation has been described based on FIG. 4.

The check node operator 815 receives data from the memory 812 depending on information on an address of the input data and information on the number of input data received from the controller 814 and performs a check node operation. Then, the check node operator 815 stores check node operation results in the memory 812 depending on information of an address of the output data and information on the number of output data received from the controller 814. Here, the check node operation has been described based on FIG. 4.

The output processor 816 performs a hard decision on whether information word bits of a codeword of a transmitter are zero (0) or one (1) based on the data received from the variable node operator 813 and then outputs a result of the hard decision, and an output value of the output processor 816 becomes a finally decoded value. In this case, in FIG. 4, the hard decision may be performed based on the sum of all message values (an initial message value and the other message values input from the check nodes) input to one variable node.

Meanwhile, the decoding apparatus 700 may further include a memory (not shown) pre-storing information on a code rate, a codeword length, and a parity check matrix of an LDPC code therein, and the LDPC decoder 710 may perform the LDPC encoding using this information. However, this is only an example. That is, corresponding information may also be provided from the transmitting side. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column.

FIG. 9 is a block diagram for describing a configuration of a receiving apparatus according to an exemplary embodiment of the present invention. As shown in FIG. 9, the receiving apparatus 900 includes a demodulator 910, a deinterleaver 920, an LDPC decoder 930, and a BCH decoder 940.

The demodulator 910 receives and demodulates a signal transmitted from the transmitting apparatus 600 (See FIG. 6). In detail, the demodulator 910 may demodulate the received signal to generate values corresponding to LDPC codewords and output the values to the deinterleaver 920.

In this case, the values corresponding to the LDPC codewords may be represented by channel values for the received signal. Here, various methods for determining the channel value may be present. As an example, a method for determining an LLR value may be used.

The deinterleaver 920 performs deinterleaving on the output values of the demodulator 910 and outputs deinterleaved values to the LDPC decoder 930.

In detail, the deinterleaver 920, which is a component corresponding to the interleaver 630 of the transmitting apparatus 600, may perform an operation corresponding to the interleaver 630. That is, the deinterleaver 920 may reversely apply the interleaving scheme applied by the interleaver 630 to deinterleave the LLR values output from the demodulator 910.

However, in some cases, when the interleaver 630 is omitted in the transmitting apparatus 600, the deinterleaver 920 may be omitted.

The LDPC decoder 930 may perform LDPC decoding using the output values of the deinterleaver 920 and output LDPC decoded bits to the BCH decoder 940. Here, the LDPC decoded bits may be a BCH codeword.

In detail, the LDPC decoder 930, which is a component corresponding to the LDPC encoder 620 of the transmitting apparatus 600, may perform the LDPC decoding based on a parity check matrix. Meanwhile, the LDPC decoder 930 of FIG. 9 may be implemented by the LDPC decoder 710 described with reference to FIG. 7. That is, the LDPC decoder 930 may perform the LDPC decoding using a parity check matrix including an information word sub-matrix defined depending on a code rate as shown in Tables 2 to 15 and a parity sub- matrix having a dual diagonal structure.

The BCH decoder 940 may perform BCH decoding on the output value of the LDPC decoder 930.

In detail, the BCH decoder 940, which is a component corresponding to the BCH encoder 610 of the transmitting apparatus 600, may perform the BCH decoding on the BCH codeword output from the LDPC decoder 930 to generate the bits transmitted from the transmitting apparatus 600. However, in some cases, when the BCH encoder 610 is omitted in the transmitting apparatus 600, the BCH decoder 940 may be omitted.

Meanwhile, the receiving apparatus 900 may pre-store various parameters used for the decoding and the deinterleaving therein. Here, the parameter used for the decoding may be information on a code rate and a codeword length of a BCH code, and a code rate, a codeword length, and a parity check matrix of an LDPC code. In addition, the parameter used for the deinterleaving may be information on a deinterleaving rule. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column.

In this case, operations of the respective components configuring the receiving apparatus 900 may be performed using these parameters.

Meanwhile, although not shown, the receiving apparatus 900 may further include a controller (not shown) for controlling an operation thereof in some cases.

In this case, the controller (not shown) may provide the information on the code rate and the codeword length of the BCH code to the BCH decoder 940 and provide the information on the code rate, the codeword length, and the parity check matrix of the LDPC code to the LDPC decoder 930. In addition, the controller (not shown) may also provide information on the interleaving scheme to the deinterleaver 920. As the information on the parity check matrix, in the case in which the parity check matrix suggested in the present embodiment is used, an information word sub-matrix is configured of a plurality of column groups each including M columns and may include a table showing positions of value of one (1) present in each M-th column. FIG. 10 is a flow chart for describing an encoding method according to an exemplary embodiment. In detail, FIG. 10 is a diagram for describing an encoding method of an encoding apparatus for performing LDPC encoding.

First, an LDPC codeword is generated by performing LDPC encoding on input bits based on a parity check matrix (S1010). Here, the LDPC codeword may be configured of 16200 bits. That is, a length of the LDPC codeword may be 16200.

Meanwhile, the parity check matrix may have the same form as that of the parity check matrix 300 shown in FIG. 3.

In detail, the parity check matrix may include an information word sub-matrix and a parity sub-matrix.

Here, the information word sub-matrix may be configured of a plurality of column groups each including M columns and be defined as a table showing positions of value of one (1) present in each M-th column. Here, M, which is an interval between repeated column patterns in the information word sub-matrix, may be 360. In addition, the parity sub-matrix may have a dual diagonal form.

In this case, in S1010, the LDPC encoding may be performed using parity check matrices differently defined depending on code rates.

For example, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 2 or Table 6 in the case in which the code rate is 7/15 and may be performed using a parity check matrix defined as a table such as Table 3, Table 7, Table 11 or Table 12 in the case in which the code rate is 9/15. In addition, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 4, Table 8 or Table 13 in the case in which the code rate is 11/15 and may be performed using a parity check matrix defined as a table such as Table 5, Table 9, Table 14 or Table 15 in the case in which the code rate is 13/15. In addition, the LDPC encoding may be performed using a parity check matrix defined as a table such as Table 10 in the case in which the code rate is 5/15.

Meanwhile, since a detailed method for performing the LDPC encoding has been described above, duplicate descriptions will be omitted.

FIG. 11 is a flow chart for describing a decoding method according to an exemplary embodiment. In detail, FIG. 11 is a diagram for describing a decoding method of a decoding apparatus for performing LDPC decoding. First, LDPC decoding is performed in an LDPC codeword based on a parity check matrix (S1110). Here, the LDPC codeword may be configured of 16200 bits. That is, a length of the LDPC codeword may be 16200.

For example, an LLR value corresponding to LDPC codeword bits passes by an iterative decoding algorithm to perform the LDPC decoding, thereby making it possible to generate information word bits.

For example, the LLR value may be represented as an LLR value that bits transmitted from a transmitting side through a channel will be 0 to likelihood that the bits will be 1. In addition, the LLR value may be a bit value itself determined depending on hard decision or be a representative value determined depending on a section to which likelihood that the bits transmitted from the transmitting side will be zero (0) or one (1) belongs.

Here, the information word sub-matrix is configured of a plurality of column groups each including M columns and is defined as a table showing positions of value of one (1) present in each M-th column. Here, M, which is an interval between repeated column patterns in the information word sub-matrix, may be 360. In addition, the parity sub-matrix may have a dual diagonal form.

In this case, in SI 110, the LDPC decoding may be performed using parity check matrices differently defined depending on code rates.

For example, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 2 or Table 6 in the case in which the code rate is 7/15 and may be performed using a parity check matrix defined as a table such as Table 3, Table 7, Table 11 or Table 12 in the case in which the code rate is 9/15. In addition, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 4, Table 8 or Table 13 in the case in which the code rate is 11/15 and may be performed using a parity check matrix defined as a table such as Table 5, Table 9, Table 14 or Table 15 in the case in which the code rate is 13/15. In addition, the LDPC decoding may be performed using a parity check matrix defined as a table such as Table 10 in the case in which the code rate is 5/15.

Meanwhile, since a detailed method for performing the LDPC decoding has been described above, detailed descriptions will be omitted.

Meanwhile, a non-transitory computer readable medium in which programs for sequentially performing the encoding method and the decoding method according to an exemplary embodiment are stored may be provided.

The non-transitory computer readable medium is not a medium in which data are stored for a short moment, such as a register, a cache, a memory, or the like, but means a medium semi-permanently storing data therein and readable by a device. In detail, various applications or programs described above may be stored in and provided from the non-transitory computer readable medium such as a compact disk (CD), a digital versatile disk (DVD), a hard disk, a blu-ray disk, a universal serial bus (USB), a memory card, a read only memory (ROM), or the like.

In addition, although buses are not shown in block diagrams showing the encoding apparatus, the decoding apparatus, the transmitting apparatus, and the receiving apparatus, communication between the respective components in the encoding apparatus, the decoding apparatus, the transmitting apparatus, and the receiving apparatus may also be performed through the buses.

Components, elements or units represented by a block as illustrated in FIGs. 5-9 may be embodied as the various numbers of hardware, software and/or firmware structures that execute respective functions described above, according to exemplary embodiments. For example, these components, elements or units may use a direct circuit structure, such as a memory, processing, logic, a look-up table, etc. that may execute the respective functions through controls of one or more microprocessors or other control apparatuses. These components, elements or units may be specifically embodied by a module, a program, or a part of code, which contains one or more executable instructions for performing specified logic functions. Also, at least one of the above components, elements or units may further include a processor such as a central processing unit (CPU) that performs the respective functions, a microprocessor, or the like.

As set forth above, according to various exemplary embodiments, LDPC encoding and decoding performance may be improved. Further, although various exemplary embodiments of the inventive concept have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the inventive concept as disclosed in the accompanying claims. Accordingly, such modifications, additions and substitutions should also be understood to fall within the scope of the inventive concept.

Claims

[CLAIMS]

[Claim 1] An encoding apparatus for performing low density parity check (LDPC) encoding, comprising: an LDPC encoder configured to generate an LDPC codeword formed of 16200 bits by performing the LDPC encoding on input bits based on a parity check matrix,

wherein the parity check matrix includes an information word sub-matrix and a parity sub-matrix, and wherein the information word sub-matrix comprises a plurality of column groups each including 360 columns and being defined as a table indicating positions of one (1) present in each 360-th column.

[Claim 2] The encoding apparatus of claim 1, wherein the LDPC encoder is configured to perform the

LDPC encoding using the parity check matrix defined as a following table when a code rate of an LDPC code is 7/15:

[Claim 3] The encoding apparatus of claim 1, wherein the LDPC encoder is configured to perform the

LDPC encoding using the parity check matrix defined as a following table when a code rate of an LDPC code is 5/15:

[Claim 4] The encoding apparatus of claim 1, wherein the LDPC encoder is configured to perform the

LDPC encoding using the parity check matrix defined as a following table when a code rate of an LDPC code is 9/15:

[Claim 5] The encoding apparatus of claim 1, wherein the LDPC encoder is configured to perform the

LDPC encoding using the parity check matrix defined as a following table when a code rate of an LDPC code is 11/15:

[Claim 6] The encoding apparatus of claim 1, wherein the LDPC encoder is configured to perform the

LDPC encoding using the parity check matrix defined as a following table when the code rate of an LDPC code is 13/15:

[Claim 7] An encoding method for performing LDPC encoding, comprising: generating an LDPC codeword formed of 16200 bits by performing the LDPC encoding on input bits based on a parity check matrix,

[Claim 8] The encoding method of claim 7, wherein in the generating the LDPC codeword, the LDPC encoding is performed using the parity check matrix defined as a following table when a code rate of an LDPC code is 7/15:

[Claim 9] The encoding method of claim 7, wherein in the generating the LDPC codeword, the LDPC encoding is performed using the parity check matrix defined as a following table when a code rate of an LDPC code is 5/15:

[Claim 10] The encoding method of claim 7, wherein in the generating the LDPC codeword, the LDPC encoding is performed using the parity check matrix defined as a following table when a code rate of an LDPC code is 9/15:

[Claim 11] The encoding method of claim 7, wherein in the generating the LDPC codeword, the LDPC encoding is performed using the parity check matrix defined as a following table when a code rate of an LDPC code is 11/15:

[Claim 12] The encoding method of claim 7, wherein in the generating the LDPC codeword, the LDPC encoding is performed using the parity check matrix defined as a following table when a code rate of an LDPC code is 13/15:

[Claim 13] A decoding apparatus for performing LDPC decoding, comprising: an LDPC decoder configured to perform the LDPC decoding on an LDPC codeword formed of 16200 bits based on a parity check matrix,

[Claim 14] The decoding apparatus of claim 13, wherein the LDPC decoder is configured to perform the

LDPC decoding using a parity check matrix defined as the following table when a code rate of an LDPC code is 7/15:

[Claim 15] The decoding apparatus of claim 13, wherein the LDPC decoder is configured to perform the

LDPC decoding using the parity check matrix defined as a following table when a code rate of an LDPC code is 5/15: